JP6512765B2 - Power reception device, power transmission device, control method performed by the power reception device, control method performed by the power transmission device, and program - Google Patents

Description

  The present invention relates to wireless power transfer technology.

  BACKGROUND Conventionally, a wireless power transmission system is known that includes a power transmission device that transmits power wirelessly and a power reception device that receives power supplied from the power transmission device. In the wireless power transmission system, there is one in which the power transmission device detects full charge of the power reception device performing power transmission and stops power transmission.

  In Patent Document 1, when the power receiving device is fully charged, which is a state where electric energy is sufficiently stored in the storage battery or the storage battery, the power receiving device sends a command indicating that the power is fully charged to the power transmission device. Is described. Furthermore, Patent Document 1 describes a technique for stopping power transmission to a power receiving device when the power transmitting device receives a command indicating that the battery is fully charged from the power receiving device.

Unexamined-Japanese-Patent No. 2010-34080

  In the wireless power transmission system as described above, prior to wireless power transmission, it is necessary to establish communication connection between the power transmission apparatus and the power receiving apparatus in order to exchange control information for wireless power transmission. As an example of the operation of the wireless power transmission system, when the power transmission device detects that the power reception device is present in the power transmittable range, the power transmission device communicates with the power reception device.

  However, if the power receiving device continues to be placed on the power transmitting device within the power transmittable range even after full charging, the power transmitting device may perform communication connection again with the fully charged power receiving device. .

  For example, when the power transmission device transmits power to the power reception device, the power reception device is fully charged, and thus the power reception device transmits a command for requesting the power transmission device to stop power transmission. The power transmission device stops the power transmission to the power receiving device in response to the reception of the command requesting the stop of the power transmission, and further disconnects the communication with the power receiving device. However, if the power receiving device continues to be placed in the power transmission range of the power transmitting device, the power transmitting device detects the power receiving device after disconnection of communication with the power receiving device, and processing for communication connection starts again. It will be done. In this case, for example, the power transmission apparatus receives a command indicating that power transmission is unnecessary from the power reception apparatus after communication connection, and wireless power transmission is not performed on the power reception apparatus. As described above, the power transmission device may transmit power and perform processing for unnecessary power transmission such as useless communication with a power reception device that is fully charged and does not require power transmission.

  This invention is an invention made in view of the above-mentioned subject, and it aims at reducing performing processing for unnecessary wireless power transmission.

As means for solving the above-mentioned problems, the power receiving device according to the present invention transmits the power receiving device receiving power wirelessly from the power transmitting device and the power transmitting device when receiving a signal for transmitting a response signal from the power transmitting device. Transmission means for transmitting the response signal, change means for changing the impedance of the power reception device, reception means for receiving an instruction for changing the impedance of the power reception device from the power transmission device, and power reception by the power reception means is unnecessary If the power transmission device is detected, the power transmission device is limited to detect the power reception device by causing the change unit to change the impedance of the power reception device based on the instruction to change the impedance received by the reception unit. Te, and a control means for performing control to limit the transmission of the signal to transmit the response signal by the power transmitting device, Characterized in that it has.

Further, a power transmission device according to the present invention includes: power transmission means for wirelessly transmitting power to the power reception device; detection means for detecting an object ; transmission means for transmitting a signal for causing the power reception device to transmit a response signal; And control means for performing control to limit transmission of a signal for causing the power reception device to transmit the response signal when the device is in a state in which power reception is not required; As a control for limiting transmission of a signal for causing the device to transmit the response signal, the transmission means includes a change in impedance for limiting detection of the power receiving device as an object by the detection means. A signal instructing the power receiving device is transmitted.

  According to the present invention, it is possible to reduce the processing for unnecessary wireless power transmission.

It is a system configuration figure of a wireless power transmission system. It is a figure which shows the structure of a power transmission apparatus. It is a figure which shows the structure of a power receiving apparatus. It is a figure which shows the sequence chart of a wireless power transmission system. It is a flow chart which shows operation of a power receiving device. It is a flow chart which shows operation of a power transmission device.

First Embodiment
The wireless power transmission system which performs wireless power transmission concerning this embodiment is shown in Drawing 1 (a). The wireless power transmission system according to the present embodiment is assumed to perform wireless power transmission using a magnetic field resonance method. The magnetic field resonance method is a method of transmitting power by coupling due to resonance of a magnetic field between a resonator (resonance element) of a power transmission device and a resonator (resonance element) of a power reception device. In the present embodiment, a wireless power transfer system using a magnetic field resonance method is described as an example, but the wireless power transfer method (contactless power transfer method) is not limited to this, and electromagnetic induction, electric field resonance, A power transmission method using microwaves, lasers, etc. may be used.

  In FIG. 1A, reference numeral 101 denotes a power transmission device, and reference numeral 102 denotes a first power reception device. The power transmission device 101 is a power transmission device that transmits power wirelessly. The first power receiving apparatus 102 is a power receiving apparatus that receives the wirelessly transmitted power. In the wireless power transmission system according to the present embodiment, communication for performing authentication and communication for control of wireless power transmission are performed between the power transmission device and the power reception device. Examples of the control information include attributes of the power receiving apparatus (type of device, etc.), power receiving capability (maximum received power, etc.), feedback information of power receiving state (power value during power receiving, etc.), and the like.

  Hereinafter, transfer of power between devices is expressed as power transmission, power reception, or power transfer (wireless power transfer), and exchange for authentication between devices or exchange of control information is simply expressed as communication (wireless communication). Do.

  In FIG. 1A, reference numeral 110 denotes a power transmittable range (power transmission range) of the power transmission apparatus 101, and 120 denotes a communicable range (communication range) of the power transmission apparatus 101. Note that frequency bands of radio waves used for wireless power transmission and wireless communication in the present embodiment are different. As shown in FIG. 1A, in the wireless power transmission system of the present embodiment, the communicable range is wider than the transmittable range of the power transmission device. This is because the frequency bands of radio waves used for wireless power transmission and wireless communication are different, and the reach of radio waves used for each is not the same. The transmittable range of the wireless power transmission is narrower than the communicable range of the wireless communication because the loss depending on the distance is large and the influence on the objects present in the transmittable range is large. In addition, if the output power of radio waves for wireless communication is reduced so that the communicable range of wireless communication and the transmittable range of wireless power transmission may be the same, communication may not be performed correctly. Therefore, in the present wireless power transmission system, the output power of radio waves for wireless communication is not reduced more than necessary, and as a result, the communicable range becomes wider than the transmittable range of the power transmission device.

  Communication performed between devices of the wireless power transmission system according to the present embodiment uses communication conforming to the Bluetooth (registered trademark) 4.0 standard. In Bluetooth (registered trademark) 4.0, a communication method capable of communicating with relatively low power consumption, such as Bluetooth (registered trademark) Low Energy (BLE), is defined. In the wireless power transmission system, the power transmission device operates as a master defined by BLE, which is a master station of the network. The power transmission device operates as a master because it is necessary to communicate with each of the plurality of power reception devices in order to transmit power to the plurality of power reception devices at one time. Further, the power receiving apparatus operates as a slave defined by BLE, which is connected to the master and performs communication based on control by the master.

  Note that although communication in the present embodiment is performed in compliance with BLE, other communication standards may be used. For example, a wireless LAN (IEEE 802.11 series), NFC (Near Field Communication), ZIGBEE, etc. may be used. Also, the communication may be a unique communication method. Although one power transmission device and one power reception device are shown here, two or more power transmission devices may be provided.

  Subsequently, the configuration of each device of the wireless power transmission system will be described. FIG. 2 is a diagram showing a configuration of a power transmission device of the wireless power transmission system. In the same figure, 210 shows the whole power transmission apparatus (power transmission apparatus 101). Reference numeral 201 denotes a control unit that controls the power transmission device 210. The control unit 201 is, for example, a central processing unit (CPU), and controls the entire apparatus by executing a control program stored in a memory 208 described later by the CPU. Reference numeral 202 denotes a power supply that supplies power when wireless power transmission is performed from the power transmission device 210. The power source 202 is a commercial power source or a battery. A power transmission unit 203 converts direct current or alternating current power input from the power supply 202 into alternating frequency power in the transmission band, and generates an electromagnetic wave for causing the power receiving apparatus to receive power via the power transmission antenna 205.

  A detection unit 204 detects an input voltage to the power transmission antenna 205. Note that the voltage detected by the detection unit 204 can be converted to the power output from the power transmission antenna 205 to the power receiving device. Further, the detection unit 204 may be configured to detect an input current to the power transmission antenna 205 and an input power value. The detection unit 204 may be configured to detect at least one of an input voltage, an input current, and an input power from the power supply unit 202 to the power transmission unit 203.

  Based on the detection result of the detection unit 204, it can be determined whether there is an object that receives the power output from the power transmission device 210. This is because the detection result of the detection unit 204 when there is no object in the power transmittable range is different from the detection result of the detection unit 204 when there is an object that consumes the transmitted power in the power transmittable range. Moreover, the change of the power consumption in the object which receives the electric power which the power transmission apparatus 210 received by the detection result of the detection part 204 can be detected. For example, when the power transmission apparatus transmits power at a constant output, the detection result of the detection unit 204 in the case where the object present in the power transmittable area consumes 1 W and the detection in the case where the object consumes 2 W It is because it is different from the result. That is, based on the detection result of the detection unit 204, when there is a change in the load for the power output from the power transmission device, it can be detected.

  A communication unit 206 communicates with the power receiving apparatus. The communication unit 206 includes a chip for controlling wireless communication compliant with BLE and an antenna for transmitting a signal. The power transmission device 210 is not limited to a device exclusively performing power transmission, but may be another device, such as a device such as a printer or a PC.

  Subsequently, the configuration of the power receiving device of the wireless power transmission system will be described with reference to FIG. In FIG. 3, reference numeral 320 denotes the entire power receiving apparatus (first power receiving apparatus 102). A control unit 301 controls the power reception device 320. The control unit 301 is, for example, a CPU, and controls the entire apparatus by executing a control program stored in a memory 310 described later by the CPU. A communication unit 302 communicates with the power transmission device 210. The communication unit 302 includes a chip for controlling BLE compliant wireless communication and an antenna for transmitting a signal. Reference numeral 303 denotes a power receiving antenna for receiving wireless power transmission from the power transmission device 210. A change unit 304 changes the impedance of the power receiving antenna 303. When the communication unit 302 receives an instruction to request a change in impedance from the power transmission device 210, the changing unit 304 changes the impedance of the power receiving antenna 303 in accordance with the instruction from the power transmission device 210 received by the communication unit 302. Changing section 304 adjusts the amount of received power of the power output from power transmission device 210 by changing the impedance of power reception antenna 303. The changing unit 304 adjusts the power consumed by the power receiving antenna 303 among the power output from the power transmission device 210 and received. That is, changing unit 304 changes the load that consumes the power received from power transmission device 210.

  A power receiving unit 305 generates power from the electromagnetic wave received by the power receiving antenna 303. The power receiving unit 305 generates resonance by the electromagnetic wave received by the power receiving antenna 303, and obtains AC power by the resonance. Then, the power receiving unit 305 rectifies AC power into DC power or AC power of a desired frequency and outputs it. A switch 306 performs input switching of received power to the battery 308 which stores received power. The battery 308 is a chargeable battery, and the received power is stored in the battery. A timer 307 measures a predetermined period. A first detection unit 309 converts the power received from the power transmission apparatus 210 into a voltage value and detects the voltage. A memory 310 stores various information. A second detection unit 311 detects the voltage of the battery 308. The charging state of the battery 308 can be detected based on the detection result of the second detection unit 311.

  Note that the control unit 301 and the communication unit 302 of the power reception device 320 may operate with the power transmitted from the power transmission device 210. By configuring in this manner, the power reception device 320 can start communication with the power transmission device 210 even when the power transmission device 210 does not hold the power necessary to start wireless power transmission. Note that an example of the power receiving device 320 may be a device such as a digital camera or a mobile phone.

  The configurations illustrated in FIGS. 2 and 3 are examples, and the power transmission device 210 and the power reception device 320 may have hardware configurations other than the illustrated hardware configuration. For example, the power transmission device 210 and the power reception device 320 may have an operation unit for the user to perform various inputs and the like to operate the device. In addition, a display unit may be provided which performs various displays such as an output of information which can be recognized visually as an LCD or an LED or a function capable of outputting a sound such as a speaker.

  The exchange between the power transmission device and the power reception device in the wireless power transmission system having the above configuration includes three phases of a detection phase, a communication establishment phase, and a power transmission phase.

  In the detection phase, by intermittently generating an electromagnetic wave from the power transmission antenna 205, power transmission (power transmission for detection) for detecting the power reception device 320 is performed intermittently. When an object is placed in the power transmittable range of the power transmission device 210 while performing power transmission for detection in the detection phase, the power transmission for detection is supplied to the object. In this case, the load impedance seen from the power transmission device 210 fluctuates, and a characteristic change in the voltage or current in the power transmission device 210 appears. By detecting the fluctuation of the voltage or current in the power transmission device 210, it is possible to detect that an object is placed in the power transmission range of the own device. In addition, when the power transmission device 210 detects that an object is present in the power transmittable area of the own device, power transmission is performed to supply the power required to cause the power transmission device 210 to transmit a response to the detected object (response request transmission). To start. When the detected object is the power reception device 320, the response request power transmission has a power value sufficient to activate the control unit 301 and the communication unit 302 of the power reception device 320. Note that the power value of the response request power transmission is larger than the power value of the detection power transmission.

  Further, the power receiving apparatus 320 that has received the response request power transmission transmits an advertise packet for transmitting a communication connection request from another device from the communication unit 302 within a fixed period (for example, 100 ms) from the response request power transmission. When the power transmission device 210 receives an advertise packet from the power reception device 320 that has responded to the response request power transmission, it determines that the power reception device 320 exists in the power transmittable range.

  An advertise packet is a signal defined in BLE transmitted by broadcast, and includes information such as its own device name and the type of service to be provided. The advertisement packet is used to notify surrounding devices of the presence of the own device and waiting for connection from the surrounding devices. The advertise packet from the power receiving apparatus 320 includes service information indicating that the wireless power transmission scheme supported by the present system can be executed. In the following description, an advertise packet is referred to as a notification signal.

  When the power transmission device 210 does not receive a notification signal from the power receiving device 320 within a predetermined period (for example, 100 ms) after the start of the response request power transmission, the power transmission device 210 stops the response request power transmission. Then, by intermittently generating an electromagnetic wave from the power transmission antenna 205 again, the detection power transmission is performed intermittently.

  The communication establishment phase transitions when the power transmission device 210 detects a notification signal from the power reception device 320 in the detection phase. The power transmission device 210 transmits a Connection Request packet (connection request) from the communication unit 206 to the power receiving device 320 that is the transmission source of the received notification signal. Then, the power transmission device 210 establishes communication connection with the power reception device 320 according to the transmitted connection request. Furthermore, in the communication establishment phase, the mutual capability information is communicated (exchanged) during the communication connection established between the power transmission device 210 and the power reception device 320. The capability information is, for example, an amount of power that can be transmitted / received, a hardware configuration, a supported power transmission scheme, a supported power transmission standard version, or the like. In the communication establishment phase, the power transmission apparatus 210 extends (continues) the response request power transmission, and performs power transmission for causing the power reception apparatus 320 to perform communication required for communication connection and communication of capability information.

  When the power transmission device 210 establishes a communication connection with the power reception device 320 in the communication establishment phase and exchanges capability information, the power transmission device 210 transitions to the power transmission phase. In the power transmission phase, the power transmission device 210 transmits, to the power receiving device 320, a power higher than the power of the detection phase, the detection power transmission in the communication establishment phase, and the response request power transmission. In the power transmission phase, the power transmission apparatus 210 receives control information for controlling wireless power transmission, such as a value of received power, a request for increase or decrease of the amount of power transmission, stop of power transmission, etc. To receive. The power transmission device 210 performs power transmission by generating an electromagnetic wave from the power transmission antenna 205 in accordance with the received control information.

  The power transmission phase ends when the power transmission device 210 is requested by the power reception device 320 to stop power transmission or when an error in power transmission occurs. When a request for stopping power transmission is received from the power receiving device 320, the power transmitting device 210 instructs the communication unit 206 to set the impedance of the power receiving antenna 303 to a value that hardly consumes the power transmitted by the power transmitting device 210. This value is about several KΩ in a state called high impedance. When receiving an instruction to change to high impedance from the power transmission apparatus 210 by the communication unit 302, the power receiving apparatus 320 controls the changing unit 304 according to the instruction to change the impedance of the power receiving antenna 303 to high impedance. The power transmission device 210 determines, based on the detection result of the detection unit 204, whether or not the power reception device 320 changes the impedance as instructed. When the power transmission device 210 determines that the impedance change is performed as instructed by the power reception device 320, the power transmission device 210 disconnects the communication with the power reception device 320.

  When the power transmission device ends the power transmission phase, the power transmission device 210 starts the operation in the detection phase again. When the power transmission device 210 starts the operation in the detection phase again, even if the power reception device 320 that has instructed high impedance continues to be within the power transmittable range, the power reception device 320 has high impedance so that power transmission for detection is performed. Consumes almost no Therefore, no change occurs in the load impedance seen from the power transmission device 210 side, and a change in voltage or current is not detected due to the power receiving device 320 that instructed the setting of the high impedance. That is, due to the power receiving device 320 instructing the setting of high impedance, it is possible to reduce the need to perform communication connection again with the power receiving device 320 that has already performed power transmission without performing response request power transmission.

  The operation of the wireless power transmission system that performs wireless power transmission according to the present embodiment will be described using the sequence chart shown in FIG. FIG. 4 is a diagram for explaining the operation of the power transmission device 101. The horizontal axis represents the passage of time, and the vertical axis represents the voltage detected by the detection unit 204 provided in the power transmission device 101.

  The power transmission device 101 starts operation in the detection phase in response to detection of power ON or an operation instruction by the user. In the detection phase, the power transmission apparatus 101 starts intermittent power transmission for detection (401-1) from the power transmission antenna 205 at time T0. Note that the cycle of detection power transmission (from time T0 to time T2) may be any value. Further, the cycle for performing detection power transmission may be set randomly for each power transmission device. Furthermore, the detection power transmission may be performed with a different cycle for each power transmission device.

  Here, the power transmission apparatus 101 stores the detection result aV of the detection unit 204 in the memory 208 at the time of steady-state detection power transmission (401-1). Note that the steady state is a state in which another device is not in proximity to or in contact with the power transmission device 210, and no power is output from the power transmission device.

  At time T1, it is assumed that the user of the first power receiving apparatus 102 has placed the first power receiving apparatus 102 on the power transmission apparatus 101 within the power transferable range of the power transmission apparatus 101 in order to receive power transmission. When the power transmission device 101 outputs power transmission for detection at time T2 due to the proximity of the power reception device, the detection unit 204 detects a voltage value bV lower than that in the steady state at the time of power transmission for detection. When the power transmission apparatus 101 outputs power in a state where an object is present within the power transferable range, the output power is received (consumed) by the object, and the detection unit 204 detects a value different from that in the steady state.

  Since the power transmission apparatus 101 detects an object close to the power transmission apparatus 101, the power transmission apparatus 101 starts response request power transmission (402-1). Note that the detection power transmission and the response request power transmission may be different power values, and the response request power transmission may be higher power than the detection power transmission. In this case, the detection result of the detection unit 204 in the steady state during response request power transmission is stored in the memory 208.

  When the first power receiving apparatus 102 detects the detection power transmission (401-2) from the power transmission apparatus 101, the first power receiving apparatus 102 transmits a notification signal from the communication unit 302 within a predetermined period (for example, 100 ms) (403-1).

  Note that the power used when the first power receiving apparatus 102 transmits the notification signal may use the power received by the detection power transmission. In this case, the power reception device can communicate with the power transmission device even when the power reception device does not hold the power necessary for transmitting the notification signal, and can start wireless power transmission.

  Since the power transmitting apparatus 101 receives the notification signal from the first power receiving apparatus 102 before the predetermined period (100 ms) elapses after the response request power transmission in 402-1, the communication establishment phase is established with the first power receiving apparatus 102. The period for response request transmission to be performed is extended between T3 and T4. On the other hand, when the power transmission apparatus 101 does not receive a notification signal from the power receiving apparatus before a predetermined period (100 ms) elapses after the response request transmission in 402-1, the response request power transmission is stopped at time T3. .

  The power transmitting apparatus 101 that has received the notification signal before the predetermined period has elapsed transmits a connection request to the first power receiving apparatus 102 that is the transmission source of the received notification signal (404-1). The first power receiving apparatus 102 communicates with the power transmitting apparatus 101 in response to the received connection request from the power transmitting apparatus 101. Thereafter, when the communication in the communication establishment phase is completed between the power transmitting apparatus 101 and the first power receiving apparatus 102, the power transmitting phase is shifted to the power transmitting phase, and the power transmitting apparatus 101 transmits the first power receiving apparatus 102 to the first power receiving apparatus 102 from time T4 to time T5. Power transmission is performed (405-1). The first power receiving apparatus 102 charges the battery 308 using the power received in the power transmission phase. If the first power receiving apparatus 102 determines from the detection result of the second detection unit 311 that power reception is not required, the communication unit 302 transmits a control signal to request power transmission stop to the power transmission apparatus 101 (406). . The state in which power reception is unnecessary is, for example, a state in which the battery 308 is fully charged (the amount of stored power remaining in the battery is sufficient).

  The power transmitting apparatus 101 that has received the control signal requesting to stop power transmission transmits an instruction to change the impedance of the power receiving antenna 303 to the high impedance to the first power receiving apparatus 102 by the communication unit 206 (407). After that, at time T5, the power transmission apparatus 101 stops power transmission in the power transmission phase for the first power receiving apparatus 102 and disconnects communication with the first power receiving apparatus 102.

  The first power receiving apparatus 102 causes the changing unit 304 to change the impedance of the power receiving antenna 303 into a high in-piece according to the instruction of the impedance change received from the power transmitting apparatus 101. Note that the power receiving antenna 303 of the first power receiving apparatus 102 changes to high in piece according to an instruction from the power transmission apparatus 101. However, regardless of the instruction from the power transmission apparatus 101, the first power receiving apparatus 102 may be configured to change the power receiving antenna 303 into a high-in-piece together with the transmission of the control signal for requesting stopping of power transmission. Further, the first power receiving apparatus 102 may disconnect communication with the power transmitting apparatus 101.

  The power transmission apparatus 101 starts the operation in the detection phase again after finishing the power transmission phase at time T5. That is, the power transmission apparatus 101 performs intermittent detection power transmission from the power transmission antenna 205 (401-3, 401-4). At this time, even after the first power receiving apparatus 102 is fully charged and power reception ends, the first power receiving apparatus 102 continues to be in the power transmittable range of the power transmission apparatus 101. However, since the first power receiving apparatus 102 sets the impedance of the power receiving antenna 303 to a high impedance, it hardly receives (consumes) power transmission for detection (401-3, 401-4). Therefore, the detection result of the detection unit 204 of the power transmission device 101 when the detection power transmission (401-3, 401-4) is performed has a value substantially equal to the steady state aV. That is, even if the first power receiving apparatus 102 continues to be placed in the power transmittable range, the power transmission apparatus 101 does not perform response request power transmission. In addition, if the response request power transmission is not performed, the notification signal is not transmitted from the first power receiving apparatus 101, and the power transmission apparatus 101 does not transmit the connection request, and the power transmitting apparatus 101 and the first power receiving apparatus 102 Unnecessary reconnection can be limited.

  This reduces the reconnection between the first power receiving apparatus 102 and the power transmitting apparatus 101 that do not require further power transmission. That is, it is reduced that the process for performing unnecessary power transmission is performed with respect to the 1st power receiving apparatus 102 by which the built-in battery was fully charged by having already performed power transmission. Furthermore, since unnecessary processing is omitted, the power consumption of each device can be reduced.

  Next, at time T6, it is assumed that the capacity of the battery 308 of the first power receiving apparatus 102 decreases and charging becomes necessary. The first power receiving apparatus 102 causes the changing unit 304 to change the impedance of the power receiving antenna 303 from the high impedance to the initial value.

  The power transmission apparatus 101 performs power transmission for detection at time T7 (401-5). The detection result of the detection unit 204 at the time of performing the detection power transmission 401-5 indicates that the impedance of the power receiving antenna 303 of the first power receiving apparatus 102 is lower than the steady state at the time of power transmission for detection It is a value bV. Although detailed description and illustration are omitted because of the above, after that, the power transmitting apparatus 101 and the first power receiving apparatus 102 retransmit the power in the power transmission phase again at time T8 through the exchange of notification signals and the communication connection phase (405 -2). As described above, when the battery needs to be charged again, the first power receiving apparatus 102 can promptly start the recharging by returning the impedance of the power receiving antenna 303 to the initial value.

  Subsequently, the operation of the power receiving device 320 shown in FIG. 3 in the present embodiment will be described according to the flowchart shown in FIG. The flowchart shown in FIG. 5 is realized by the control unit 301 executing a control program stored in the memory 310 to execute calculation and processing of information and control of each hardware. Note that part or all of the steps shown in the flowchart of FIG. 5 may be realized by hardware such as an application specific integrated circuit (ASIC).

  When operation starts, the changing unit 304 of the power receiving device 320 sets the impedance of the power receiving antenna 303 to an initial value (S500). Subsequently, the first detection unit 309 of the power reception device 320 determines whether detection power transmission has been detected via the power reception antenna 303 (S501). When the power reception device 320 detects power transmission for detection, the power reception device operates the control unit 301 and the communication unit 302 with the received power, and the communication unit 302 notifies the information of the own device such as information on functions and services of the power reception device 320. The notification signal of is transmitted (S502). The notification signal is a packet that can be transmitted before making a wireless connection, and is transmitted by broadcast in order to cause the peripheral device to transmit a connection request to the own device. The transmission of the notification signal is stopped when a certain period of time elapses after the detection power transmission is not detected.

  In FIG. 4, the first power receiving apparatus 102 detects the detection power transmission transmitted from the power transmission apparatus 101 at time T2 (S501). Then, the first power receiving apparatus 102 transmits a notification signal 403-1 (S502).

  Returning to the explanation of FIG. 5, after transmitting the notification signal, the control unit 301 determines whether the communication unit 302 has received a connection request from the power transmission device 210 (S 503). Note that S501, S502, and S503 are repeated until a connection request is received. If it is determined in S503 that the connection request has been received, the communication unit 302 transmits a connection response to the power transmission device 210, and establishes a wireless communication connection with the power transmission device 210 (S504).

  Then, the communication unit 302 performs communication for exchanging information necessary for power transmission with the connected power transmission device 210 (S505). If communication is not started by the elapse of a predetermined period (for example, 5 seconds) after the wireless communication connection, the communication with the connected power transmission apparatus 210 may be disconnected, and the process may be returned to S501.

  When the communication for exchanging information necessary for the power transmission ends, the power receiving device 320 receives the power transmission started by the power transmitting device 210 by the power receiving unit 305, and charges the received power to the battery 308 (S506).

  Thereafter, the control unit 301 determines whether to stop power reception based on the detection result of the second detection unit 311 (S507). Here, when it is detected from the detection result of the second detection unit 311 that the battery 308 is fully charged, it is determined that the power reception is to be stopped. If it is determined that power reception is to be stopped, the communication unit 302 transmits control information for requesting the power transmission device 210 to stop power transmission (S508). In FIG. 4, the first power receiving apparatus 102 transmits the control signal 406 after receiving the power transmission 405-1 from the power transmission apparatus 101.

  Then, when the control unit 301 receives the impedance change instruction from the power transmission apparatus 210 by the communication unit 302, the control unit 301 changes the impedance of the power receiving antenna 303 according to the impedance change instruction received by the change unit 304 (S509). That is, the changing unit 304 changes the impedance of the power receiving antenna 303 to high impedance in accordance with the impedance change instruction from the power transmission device 210. Then, the power receiving device 320 disconnects the communication with the power transmitting device 210 by the communication unit 302. In FIG. 4, when receiving the change instruction 407 from the power transmission apparatus 101, the first power receiving apparatus 102 changes the impedance of the power receiving antenna 303 to a high impedance. The power receiving apparatus 320 changes the impedance of the power receiving antenna 303 to high impedance, and then disconnects the communication by the communication unit 302 with the power transmitting apparatus 210 (S510).

  The control unit 301 measures the amount of electricity of the battery 308 based on the detection result of the second detection unit 311, and determines whether the remaining amount of the battery 308 has decreased (S511). The control unit 301 determines whether or not it is necessary to receive power again based on whether or not the remaining amount of the battery 308 falls below a predetermined value (for example, 95%) (S512). In addition, when the power receiving device 320 is removed from the transmittable range of the power transmission device 210, it is determined that no re-power reception is necessary.

  When it is determined that the re-power reception is necessary, the control unit 301 then performs the process from S500 again. On the other hand, when it is determined that the re-power reception is not necessary, the process ends.

  Subsequently, the operation of the power transmission device 210 shown in FIG. 2 in the present embodiment will be described according to the flowchart shown in FIG. The flowchart illustrated in FIG. 6 is realized by the control unit 201 executing a control program stored in the memory 208 to execute calculation and processing of information and control of each hardware. Note that part or all of the steps shown in the flowchart of FIG. 6 may be realized by hardware such as an ASIC.

  When the power transmission device 210 starts operation, the power transmission unit 203 starts intermittent power transmission for detection (S601). The control unit 201 determines whether or not the load impedance seen from the power transmission device 210 has changed based on whether the detection result of the detection unit 204 at the time of power transmission for detection has changed from the steady state (S602). Note that the steady state is a state in which another device is not in proximity to or in contact with the power transmission device 210. In FIG. 4, the power transmission device starts power transmission for detection at time T0.

  The control unit 201 detects the presence of an object in the power transmittable area of the own device based on the detection result of the detection unit 204. That is, when the power receiving device 320 exists in the power transmittable area of the power transmitting device 210, the power consumption corresponding to the load of the power receiving device 320 is received, so the detection voltage of the detection unit 204 decreases by a constant value. The power consumption according to the load of the power receiving device 320 is the power necessary for operating the control unit 301 and the communication unit 302 or the power consumed simply by the power receiving antenna 303. If there is no change in the detection voltage of the detection unit 204, the process returns to S601 to repeat the power transmission for detection. In FIG. 4, the power transmission apparatus 101 detects a change in the detection voltage of the detection unit 204 at time T2.

  If a change occurs in the detection voltage of the detection unit 204, the power transmission unit 203 starts response request power transmission for supplying power for causing the power reception device 320 to transmit a response (S603). The response request power transmission, unlike the detection power transmission which is intermittently performed, is a power transmission which continuously transmits constant power. The control unit 201 determines whether a notification signal has been received from the power receiving device 320 within a certain period (for example, 100 ms) after the response request power transmission has been started (S604). It is determined whether or not the notification signal from the power receiving device 320 is based on whether or not the received notification signal includes service information indicating that the wireless power transmission method compatible with the present system can be executed. When the notification signal is not received, the response request power transmission is stopped, and the process returns to S601 to perform power transmission for detection.

  If it is determined in S604 that the notification signal has been received from the power receiving device 320 within a predetermined period, the power transmitting device 210 continues the response request power transmission. Then, the power transmission apparatus 210 transmits a connection request from the communication unit 302 to the transmission source of the notification signal received in S604, and wireless communication connection is established (S605). In FIG. 4, the power transmission apparatus 101 receives the notification signal (403-1) from the first power receiving apparatus 102 within a certain period after starting the response request power transmission (402-1). Then, the power transmitting apparatus 101 transmits a connection request (404-1) to the first power receiving apparatus 102, and wirelessly connects with the first power receiving apparatus 102.

  The communication unit 206 communicates (exchanges) each other's capability information and information necessary for power transmission with the power receiving apparatus 320 wirelessly connected in S605 (S606). Then, the power transmission unit 203 starts wireless power transmission in the power transmission phase (S607).

  If the control unit 201 receives a request for stopping power transmission from the power receiving apparatus 320 from the communication unit 206 after starting power transmission, the control unit 201 determines to stop power transmission (S608). If it is determined that the power transmission is to be stopped, the power transmitting apparatus 210 transmits an impedance change instruction from the communication unit 302 to the power receiving apparatus 320 that is the transmission source of the power transmission stopping request (S609). The impedance change instruction transmitted in S609 is an instruction to change the impedance of the power receiving antenna 303 to high impedance. In FIG. 4, when the power transmission device 101 receives a power transmission stop request (406) from the first power reception device 102, the power transmission device 101 transmits an impedance change instruction (407).

  After transmitting the impedance change instruction, the power transmission device 210 stops the power transmission to the power receiving device 320 that is the transmission source of the request to stop the power transmission (S610), and disconnects the communication with the power receiving device (S611). Next, the control unit 201 determines whether there is another power receiving device currently transmitting power (S612). If there is another power receiving device currently transmitting power, power transmission to the other power receiving device is continued (S607). If there is no other power receiving device that is transmitting power, the power transmitting device 210 executes the process from S601 again as long as the power supply is not stopped. In addition, the power transmission apparatus 210 complete | finishes a process, when a power supply is stopped (S613). Although the determination of step S613 is performed after step S612, the determination may be performed at any timing during processing.

  As described above, it is necessary to recharge the power receiving device even if the power receiving device which has been fully charged by charging by wireless power transmission and has finished receiving power continues to be disposed in the power transmittable range of the power transmitting device. If not, it restricts the reconnection of the communication between the power receiving device and the power transmitting device.

  As described above, by limiting unnecessary reconnection between the power receiving device and the power transmitting device, performing processing for performing unnecessary power transmission can be reduced. Furthermore, since unnecessary processing is omitted, the power consumption of each device can be reduced.

  In the embodiment described above, the configuration has been described in which the power transmission device 210 does not perform the response request power transmission because the power reception device 320 after full charge becomes high impedance and the power transmission device 210 can not detect the power reception device 320. However, unnecessary reconnection is performed even if the power receiving device 320 does not transmit the notification signal when receiving the response request power transmission from the power transmitting device 210 instead of setting the power receiving device 320 after full charge to high impedance. Can be limited. When the battery of the power receiving device 320 after full charge needs to be recharged, the notification signal may be transmitted when the response request power transmission is received.

  In the above-described embodiment, reconnection between the power transmission device 210 and the power receiving device 320 that is fully charged by power transmission is limited. However, when the power receiving device 320 in a state in which power reception is not required is placed within the transmittable range of the power transmitting device 210, the wireless communication connection between the power receiving device 320 and the power transmitting device 210 may be controlled. . In this case, when receiving the response request power transmission from the power transmission device 210, the power reception device 320 transmits an advertise packet including information indicating that power reception is not required. The power transmitting apparatus 320 that has received the advertise packet including the information indicating that power reception is not required is prevented from transmitting a connection request to the power receiving apparatus 320 that is the transmission source of the advertise packet. With such a configuration, unnecessary wireless communication connection with the power receiving device 320 can be reduced even when the power receiving device 320 in a state in which power reception is unnecessary is placed within the power transmittable range.

Second Embodiment
The wireless power transmission system which performs wireless power transmission concerning this embodiment is shown in Drawing 1 (b). As a difference from the first embodiment, a case where the power transmission apparatus 101 transmits power to not only the first power receiving apparatus 102 but also the second power receiving apparatus 103 will be described.

  Specifically, while the power transmission device 101 is transmitting power to the first power reception device 102, the second power reception device 103 is disposed in the power transmittable range of the power transmission device 101. Then, the power transmission device 101 performs power transmission to the first power reception device 102 and the second power reception device 103 simultaneously. Next, when the first power receiving apparatus 102 is fully charged and no power reception is necessary, and the power transmitting apparatus 101 transmits power to the second power receiving apparatus 103, the first power receiving apparatus 102 can transmit power. The operation in the case of continuing to be arranged in the range will be described.

  The configurations of the power transmission device 101, the first power reception device 102, and the second power reception device 103 according to the present embodiment are the same as those of the first embodiment, and thus the description thereof will be omitted. The power transmission device 101 according to the present embodiment can perform the same operation as the power transmission device 210 described in the first embodiment. The first power receiving apparatus 102 and the second power receiving apparatus 103 according to the present embodiment can perform the same operation as the power receiving apparatus 320 described in the first embodiment. The power transmission device 101 of the present embodiment can perform power transmission to a plurality of power reception devices 320. In this case, the power transmission apparatus 101 performs power transmission to each of the plurality of power reception apparatuses 320 in a time division manner, and transmits power to each of the plurality of power reception apparatuses 320 using electromagnetic waves of different frequencies used for power transmission. Thus, power is transmitted to the plurality of power receiving devices 320.

  It is assumed that the second power receiving apparatus 103 is disposed in the power transmittable range of the power transmitting apparatus 101 while the power transmitting apparatus 101 is transmitting power to the first power receiving apparatus 102. At this time, since the power transmission apparatus 101 is in a power transmission phase for performing power transmission to the first power receiving apparatus 102, power transmission for detection is not performed. Therefore, when the power receiving device (the first power receiving device 102, the second power receiving device 103) according to the present embodiment is disposed in the power transmittable range of the power transmission device 101, when power transmission in the power transmission phase to another power receiving device is detected, A notification signal is transmitted to wirelessly connect to the power transmission apparatus 101. With this configuration, even when a power transmission device capable of transmitting power to a plurality of power reception devices is transmitting power to a certain power reception device, it is possible to perform power transmission by adding a new power reception device.

  However, if the power transmitting apparatus 101 is transmitting power to the first power receiving apparatus 102 and the second power receiving apparatus 103, power transmission continues if the power transmitting apparatus 101 continues to be disposed in the power transmittable range even after the first power receiving apparatus 102 is fully charged. There is a possibility that the device 101 again performs communication connection with the first power receiving device 102.

  For example, since the first power receiving apparatus 102 is fully charged, the first power receiving apparatus 102 transmits a power transmission stop request to the power transmission apparatus 101. In response to the reception of the power transmission stop request, the power transmission apparatus 101 stops power transmission to the first power receiving apparatus 102 and disconnects communication with the first power receiving apparatus 102. However, even if the power transmission to the first power receiving apparatus 102 is stopped, since the power transmission to the second power receiving apparatus 103 is continued, the power transmission apparatus 101 does not shift to the detection phase and remains in the power transmission phase.

  Therefore, when the first power receiving apparatus 102 continues to be placed in the power transmission range of the power transmitting apparatus 101 after that, the first power receiving apparatus 102 that has detected power transmission to the second power receiving apparatus 103 transmits a notification signal. Then, in response to the notification signal from the first power receiving apparatus 102, the power transmitting apparatus 101 may reestablish communication connection with the first power receiving apparatus 102.

  As described above, the power transmission apparatus 101 capable of transmitting power to a plurality of power receiving apparatuses has already performed power transmission, and performs unnecessary power transmission processing on the first power receiving apparatus 102 that is fully charged and does not require power transmission. There are times when

  In order not to cause such a problem, the power receiving device of the present embodiment restricts reconnection with the power transmitting device 101 even if power transmission to another power receiving device is detected after being fully charged. That is, when the power receiving device is fully charged and power reception from the power transmission device 101 is stopped and communication with the power transmission device 101 is cut off, the device continues to be disposed in the power transmittable range and power transmission to another power receiving device is received To be configured not to transmit a notification signal.

  That is, when the power reception device of the present embodiment detects power transmission of another power reception device when power reception to the own device is necessary, the power reception device transmits a notification signal and performs processing for establishing wireless connection with the power transmission device. . On the other hand, when power reception has already ended and further power reception is unnecessary, even if power transmission of the power transmission device to another power reception device is detected, the notification signal is not transmitted and wireless connection with the power transmission device is restricted.

  In addition, when the first power receiving apparatus 102 after full charge needs to be recharged, the restriction on the transmission of the notification signal is released and the communication signal with the power transmission apparatus 101 is established again by transmitting the notification signal. If it does, it should just be made to start power transmission of a power transmission phase again.

  As described above, in a state where the power receiving device which is fully charged by wireless power transmission and whose power reception has ended is continuously disposed in the power transmittable range of the power transmitting device, and the power transmitting device performs power transmission to another power receiving device. Even if there is, the communication reconnection between the power receiving device and the power transmitting device is restricted.

  Thus, by limiting unnecessary reconnection between the power receiving device and the power transmitting device, it is possible to reduce processing for performing unnecessary power transmission. Furthermore, since unnecessary processing is omitted, the power consumption of each device can be reduced.

(Other embodiments)
The present invention supplies a program that implements one or more functions of the above-described embodiments to a system or apparatus via a network or storage medium, and one or more processors in a computer of the system or apparatus read and execute the program. Can also be realized. It can also be implemented by a circuit (eg, an ASIC) that implements one or more functions.

101 first power transmission device 102 first power reception device 103 second power transmission device

Claims (18)

A power receiving device,
Power receiving means for wirelessly receiving power from the power transmission device;
Transmitting means for transmitting the response signal to the power transmission device when receiving a signal for transmitting the response signal from the power transmission device;
Changing means for changing the impedance of the power receiving device;
A receiving unit configured to receive an instruction to change the impedance of the power reception device from the power transmission device;
When the power receiving unit does not need to receive power, the power transmission device receives the power by causing the changing unit to change the impedance of the power receiving device based on the instruction to change the impedance received by the receiving unit. A control unit configured to perform control for limiting transmission of a signal for transmitting the response signal by the power transmission device while restricting detection of the device.   The power receiving device according to claim 1, wherein the signal for transmitting the response signal is transmitted when the power transmitting device detects an object.   The said control means makes the said change means change the impedance of the said call | power receiving apparatus, when it becomes a state which becomes unnecessary from the state which makes power reception by the said call reception means unnecessary. Power receiving device.   4. The apparatus according to any one of claims 1 to 3, wherein the state in which power reception by the power reception means is not required is a state in which storage means for storing the power received by the power reception means is fully charged The power receiving device described. It further comprises detection means for detecting the storage state of the storage means,
5. The power receiving apparatus according to claim 4, wherein the transmitting unit transmits a signal for stopping power transmission to the power transmitting apparatus when the detecting unit detects a state in which the storage unit is fully charged. .   The control unit causes the transmission unit to transmit the response signal by the power transmission apparatus by causing the transmission unit to transmit a signal for stopping the power transmission when the power reception unit does not need to receive the power. The power reception device according to any one of claims 1 to 5, characterized in that transmission of a signal for transmission is limited. It further comprises communication means for communicating wirelessly with the power transmission device,
The said communication means communicates with the said power transmission apparatus by radio | wireless according to the response from the said power transmission apparatus with respect to the said response signal transmitted by the said transmission means. The power receiving device described.   The power receiving device according to claim 7, wherein a frequency band of the electromagnetic wave used for power reception by the power receiving means and a frequency band of the electromagnetic wave used for communication by the communication means are different. Power transmission means for wirelessly transmitting power to the power receiving device;
Detection means for detecting an object ;
Transmission means for transmitting a signal for causing the power reception device to transmit a response signal;
And control means for performing control to limit transmission of a signal for causing the power reception device to transmit the response signal when the power reception device is in a state in which power reception is not required.
The control means limits the transmission means to detect that the power receiving device is detected as an object by the detection means as control for limiting transmission of a signal for causing the power receiving device to transmit the response signal. And a power transmission device configured to transmit a signal instructing the power reception device to change the impedance.   The power transmission device according to claim 9, wherein the signal for causing the power reception device to transmit a response signal is transmitted when an object is detected by the detection unit. It further comprises a communication unit that communicates wirelessly with the power receiving device,
11. The power transmission device according to claim 9, wherein the communication unit wirelessly communicates with the power reception device according to a response signal transmitted from the power reception device.   The power transmission device according to claim 11, wherein a frequency band of the electromagnetic wave used for power transmission by the power transmission means and a frequency band of the electromagnetic wave used for communication by the communication means are different. A control method performed by the power receiving apparatus,
A power receiving step of wirelessly receiving power from the power transmission device;
A transmitting step of transmitting the response signal to the power transmission device when receiving a signal for transmitting a response signal from the power transmission device;
A changing step of changing the impedance of the power receiving device;
A receiving step of receiving, from the power transmission device, an instruction to change the impedance of the power reception device;
When the power receiving device is in a state not requiring power reception, the power transmission device receives the power reception by changing the impedance of the power receiving device in the changing step based on the instruction of changing the impedance received in the receiving step. A control step of performing control for limiting transmission of a signal for causing the power transmission device to transmit the response signal by limiting detection of the device.   The control method according to claim 13, wherein the signal for transmitting the response signal is transmitted when the power transmission device detects an object. A control method performed by the power transmission device,
A power transmission step of wirelessly transmitting power to the power receiving device;
A detection step of detecting an object ;
A transmitting step of transmitting a signal for causing the power receiving device to transmit a response signal;
And a control step of performing control to limit transmission of a signal for causing the power reception device to transmit the response signal when the power reception device is in a state in which power reception is not required.
In the control step, as control for limiting transmission of a signal for causing the power reception device to transmit the response signal, change in impedance for limiting detection of the power reception device as an object in the detection step And transmitting a signal instructing the power receiving apparatus to   The control method according to claim 15, wherein the signal for causing the power reception device to transmit a response signal is transmitted when an object is detected in the detection step.   A program for executing a computer as each means of the power receiving device according to any one of claims 1 to 8.   A program for executing a computer as each means of the power transmission device according to any one of claims 9 to 12.

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